KR100314429B1 - Runaway prevention device for microcomputer - Google Patents

Abstract

The present invention relates to an apparatus for preventing runaway of a microcomputer, and more particularly, to an apparatus for preventing runaway that can suppress an output signal that can be generated by the runaway of a microcomputer.

An apparatus for preventing runaway of a microcomputer of the present invention includes an inverter circuit for supplying a high frequency voltage to a working coil; A microcomputer controlling a switching time of the inverter circuit; Monitoring means for monitoring the congestion of the microcomputer; And suppressing means for suppressing the output from the microcomputer to the inverter circuit by the output of the monitoring means.

Description

Microcomputer runaway prevention device.

The present invention relates to an apparatus for preventing runaway of a microcomputer, and more particularly, to an apparatus for preventing runaway that can suppress an output signal that can be generated by the runaway of a microcomputer.

1 illustrates a control configuration diagram of a microcomputer of a conventional induction heating cooker.

A conventional induction heating cooker is a transformer 10 for inputting 220 volts AC power from the outside, stepped up to a voltage of a predetermined size and output to the secondary side, and the first terminal a and the secondary side of the transformer 10. On / off switching between the first rectifier 20 connected to the two terminals b for rectifying and outputting the input power and the 22 volt DC voltage connected to the output terminal of the first rectifier 20 for a predetermined period. Inverter circuit 30 is converted to a high frequency voltage to output to the working coil.

That is, the inverter circuit unit 30 is configured to supply a high frequency current to a working coil (not shown). The working coil is driven by the switching voltage of the inverter circuit unit 30 and is applied to the working coil. When the voltage is cut off, the heating coil is not heated.

In addition, the conventional induction heating cooker is connected between the second side third terminal (c) and the fourth terminal (d) of the transformer 10, the second rectifier 50 for rectifying and outputting the input power, and And a microcomputer 40 which is connected to an output terminal of the second rectifier 50 and driven by a 12 volt DC power source applied to control the system.

The microcomputer 40 outputs signals for controlling the on / off switching cycle of the inverter circuit unit 30 to two output terminals LSB and MSB. The output terminal LSB outputs a signal at low output, and the output terminal MSB outputs a signal at high output.

The on / off switching period control signal output from the microcomputer 40 is input to the output voltage level determination unit 60 through the resistors R1 and R2, and the output voltage level determination unit 60 is an input signal. The on-time control signal for the operation of the inverter circuit unit 30 is output based on the. Thereafter, the driving coil is driven while generating a high frequency voltage in the inverter circuit unit 30.

The microcomputer 40 is a component that controls the overall operation of the system. Thus, by the 12-volt power supplied from the transformer 10, the microcomputer 40 maintains a standby state that can be driven at all times, and then recognizes a user command signal applied by an external key operation and performs control accordingly.

Operation of the conventional induction heating cooker having the above configuration is made as follows.

First, the transformer 10 continuously inputs 220 volts of AC power to the primary side, and boosts the input power to output 22 volts and 12 volts. 22 volts output from the transformer 10 is input to the inverter circuit unit 30 through the rectifying unit 20. Therefore, the inverter circuit unit 30 is in a standby state until a control signal for on-time control of the switching element in the circuit unit is applied.

On the other hand, the 12 volt DC power output to the secondary side of the transformer 10 is input to the microcomputer 40, the microcomputer 40 maintains a state capable of operation at any time using the 12 volt power.

Therefore, when a cooking start signal of the induction heating cooker is input to the microcomputer 40 by a user by operating an external key, the microcomputer 40 outputs an on-time control signal for driving the inverter circuit unit 30. This control signal is determined by the resistors R1 and R2, and the voltage level of V1 is determined, and this signal is input to the inverter circuit section 30 through the output voltage level setting unit 60. At this time, the inverter circuit unit 30 generates a high frequency voltage using a 22-volt power input from the power input terminal.

In the above, the microcomputer 40 outputs an on-time control signal for driving the inverter circuit unit 30 by an external key operation. This on-time control signal has a value of V1 determined by the resistors R1 and R2, and this value becomes a voltage value for determining the output of the inverter circuit section 30 in the output voltage level determining section 60.

On the other hand, the microcomputer 40 is a control device that generates an output by an external key input signal. Therefore, there is a possibility that runaway may occur due to external noise, and if an output is generated from the output terminals LSB and MSB of the microcomputer 40 at a time other than the output section, damage to the circuit element may occur. .

In particular, since the switching element in the inverter circuit section 30 is used as a means for generating a high frequency voltage, a very expensive semiconductor element is used. Therefore, when the congestion signal is generated from the output terminal of the microcomputer 40 at a time other than the output section, there is a problem that the switching element is damaged.

Accordingly, an object of the present invention is to provide a microcomputer runaway prevention device capable of muting this signal when a runaway occurs in the microcomputer.

1 is a control block diagram of a conventional induction heating cooker,

2 is a control block diagram of an induction heating cooker according to the present invention.

Explanation of symbols on the main parts of the drawings

10,15: transformer 20,25,50,55: rectifier circuit

30,35: inverter circuit 40,45: microcomputer

60,65: output voltage level determining section R1 to R4: resistance

D1, D2: Diode Q1: Transistor

An apparatus for preventing runaway of a microcomputer according to the present invention for achieving the above object includes an inverter circuit for supplying a high frequency voltage to the working coil; A microcomputer controlling a switching time of the inverter circuit; Monitoring means for monitoring the congestion of the microcomputer; And suppressing means for suppressing the output from the microcomputer to the inverter circuit by the output of the monitoring means.

The present invention is characterized in that circuit induction is prevented by suppressing an output signal that may be generated by congestion of a microcomputer in an induction heating cooker.

Accordingly, the present invention includes monitoring means for monitoring whether congestion has occurred at the microcomputer output. And when the runaway occurs, muting the output signal for on-time control of the inverter circuit.

That is, the present invention prevents damage to the circuit elements due to congestion of the microcomputer while bringing the effect of increasing the reliability of the product.

Hereinafter, with reference to the accompanying drawings will be described in detail the runaway prevention device of a microcomputer according to the present invention.

The induction heating cooking apparatus of the present invention is a transformer 15 for inputting a 220 volt AC power source from the outside, stepped up to a predetermined voltage and output to the secondary side, and the secondary terminal first terminal (a) of the transformer 15. And a first rectifier 25 connected to the second terminal b to rectify and output the input power, and a 22 volt DC voltage connected to an output terminal of the first rectifier 25 and applied at a constant cycle. The inverter circuit unit 35 is switched off to be converted to a high frequency voltage and output to the working coil.

That is, the inverter circuit unit 35 is configured to supply a high frequency current to a working coil (not shown). The working coil is driven by the switching voltage of the inverter circuit unit 35, and is applied to the working coil. When the voltage is cut off, the heating coil is not heated.

In addition, the induction heating cooker of the present invention is connected between the secondary terminal third terminal (c) and the fourth terminal (d) of the transformer 15, the second rectifying unit 55 for rectifying and outputting the input power, And a microcomputer 45 connected to the output terminal of the second rectifying unit 55 and driven by a 12 volt DC power source applied to control the system.

The microcomputer 45 outputs signals for controlling the on / off switching cycle of the inverter circuit unit 35 to two output terminals LSB and MSB. The output terminal LSB outputs a signal at low output, and the output terminal MSB outputs a signal at high output.

The on / off switching period control signal output from the microcomputer 45 is input to the output voltage level determination unit 65 through the resistors R1 and R2, and the output voltage level determination unit 65 is an input signal. The on-time control signal for the operation of the inverter circuit unit 35 is output based on the above. Thereafter, the driving coil is driven while generating a high frequency voltage in the inverter circuit unit 35.

The microcomputer 45 is a component that controls the overall operation of the system. Thus, by the 12-volt power supplied from the transformer 15, the microcomputer 45 maintains the standby state which can always be driven, and then recognizes the command signal applied by the external key manipulation by the user input and performs the control accordingly. Done.

In the configuration of the present invention, a configuration for suppressing runaway from the output terminals LSB and MSB of the microcomputer is included between the microcomputer 45 and the output voltage level determining section 65. FIG.

In the configuration for preventing runaway of the present invention, the collector terminal of the transistor Q1 is connected to the rear end of the resistor R1 connected to the first output terminal LSB of the microcomputer 45 through the diode D1. In addition, the collector terminal of the transistor Q1 is connected through the diode D2 to the rear end of the resistor R2 connected to the second output terminal MSB of the microcomputer 45. That is, the diodes D1 and D2 are connected to the collector terminal of the same transistor Q1.

The emitter terminal of the transistor Q1 is connected to the ground potential, and the base terminal and the emitter terminal are connected through the resistor R4. The base terminal of the transistor Q1 is connected to the output terminal P1 of the microcomputer 45 through a resistor R3.

The output terminal P1 of the microcomputer 45 is configured to monitor the outputs of the first and second output terminals LSB and MSB of the microcomputer and output a high signal when it is determined that congestion has occurred. The congestion determination of the microcomputer is a congestion when the output of the microcomputer keeps outputting the same output without a state transition for a predetermined time or when the outputs of the first and second output terminals of the microcomputer simultaneously output high signals. I judge it.

Next, a description will be given of the operation of the microcomputer runaway prevention device according to the present invention having the above configuration.

The transformer 15 continuously inputs 220 volts of AC power to the primary side, and boosts the input power to output 22 volts and 12 volts. The 22 volts output from the transformer 15 is input to the inverter circuit unit 35 through the rectifier 25. Accordingly, the inverter circuit unit 35 is in a standby state until a control signal for on-time control of the switching element in the circuit unit is applied.

On the other hand, the 12 volt DC power output to the secondary side of the transformer 15 is input to the microcomputer 45, the microcomputer 45 maintains a state capable of operation at any time using the 12 volt power.

Therefore, when a cooking start signal of the induction heating cooker is input to the microcomputer 45 by the user by the external key manipulation, the microcomputer 45 outputs an on-time control signal for driving the inverter circuit unit 35. This control signal is determined at the voltage level of V1 through the resistors R1 and R2, and this signal is input to the inverter circuit section 35 through the output voltage level determination section 65. In this case, the inverter circuit unit 35 is switched to the control signal of the output voltage level determination unit 65 to generate a high frequency voltage using the 22-volt power input from the power input terminal.

In the above, the microcomputer 45 outputs an on-time control signal for driving the inverter circuit unit 35 by an external key operation. This on-time control signal has a value of V1 determined by the resistors R1 and R2, and this value becomes a voltage value for determining the output of the inverter circuit section 35 in the output voltage level determining section 65.

On the other hand, the microcomputer 45 is a control device that generates an output by an external key input signal. Thus, when an output is generated from the output terminals LSB and MSB of the microcomputer 45 at a time other than the output section, this signal is applied to the collector terminal of the transistor Q1 while conducting the diodes D1 and D2.

At this time, the output of the microcomputer 45 output terminals LSB and MSB is monitored by the output terminal P1 of the microcomputer 45. That is, when the high signal is continuously output from the output terminals LSB and MSB of the microcomputer 45 for a predetermined time or the same signal is generated from the two terminals, it is determined that the congestion occurs in the microcomputer, A high signal is output at (P1).

The high signal turns on the transistor Q1, so that the high signal outputs of the first and second output terminals LSB and MSB of the microcomputer 45 which are applied to the collector terminal of the transistor Q1 are It flows to the ground potential through the transistor Q1. Therefore, the V1 potential level is turned low, and the operation of the output level determining section 65 is turned off.

Next, while the low signal is being output from the output terminal P1 of the microcomputer 45, the output signals of the first and second output terminals LSB and MSB receive the potential of V1 through the resistors R1 and R2. The signal thus determined is input to the output level determining section 65 to determine the on-time control signal of the inverter circuit section 35.

As described above, the microcomputer runaway prevention device according to the present invention suppresses the drive of the inverter by suppressing the output signal when the runaway of the microcomputer occurs. Therefore, despite the fact that the output is not generated by the congestion of the microcomputer, when the signal is output from the microcomputer, the problem of damage to the circuit elements in the inverter circuit is damaged by a simple circuit configuration, and the product reliability is increased. It can bring an effect.

Claims (2)

An inverter circuit for supplying a high frequency voltage to the working coil; A microcomputer outputting an on-time control signal for driving the inverter circuit and outputting a runaway generation signal when an abnormality occurs in the on-time control signal; And a runaway generation means for blocking the on-time control signal output from the microcomputer by the runaway generation signal of the microcomputer. The method of claim 1; The runaway generation means includes: mute means for muting an on-time control signal switched by the runaway generation signal; And a diode connected between the on-time control signal output terminal of the microcomputer and the muting means.